AI Article Synopsis
- Miniature resonant piezoelectric robots are garnering attention for their small size, quick response, and simple control, but often struggle with flexibility due to limited movement at their feet.
- Drawing inspiration from earthworms, researchers designed a piezoelectric robot with feet arranged circumferentially to enhance adaptability and introduced a new actuation principle to mimic the earthworm's movement patterns.
- The robot weighs 22.7 g, has compact dimensions, and can move at speeds up to 179.35 mm/s on diverse surfaces, showcasing its ability to navigate challenging environments effectively.
Article Abstract
Miniature resonant piezoelectric robots have the advantages of compact structure, fast response, high speed, and easy control, which have attracted the interest of many scholars in recent years. However, piezoelectric robots usually suffer from the problem of poor adaptability due to the micron-level amplitude at the feet. Inspired by the fact that earthworms have actuation trajectories all around their bodies to move flexibly under the ground, a miniature piezoelectric robot with circumferentially arranged driving feet to improve adaptability is proposed. Notably, a longitudinal-vibration-compound actuation principle with multilegged collaboration is designed to achieve the actuation trajectories around the robot, similar to the earthworms. The structure and operating principle are simulated by the finite element method, and the prototype is fabricated. The robot weighs 22.7 g and has dimensions of 35.5 × 36.5 × 47 mm. The robot is tethered to an ultrasonic power supply, and the experimental results show that the speed reaches 179.35 mm s under an exciting signal with a frequency of 58.5 kHz and a voltage of 200 V. High adaptability is achieved by the proposed robot, it can move on flat, fold, concave, and convex surfaces, and even in an inclined or rotating tube.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11304247 | PMC |
| http://dx.doi.org/10.1002/advs.202403426 | DOI Listing |
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